Digital data storage assembly

ABSTRACT

A digital data storage assembly ( 2 ), e.g., a flexible thin film compact disc, is described. Digital data storage assembly ( 2 ) includes, (a) a thin film data storage carrier ( 11 ), having substantially opposed first ( 14 ) and second ( 17 ) surfaces, an aperture ( 20 ), and at least one tab ( 23, 26 ) extending partially into aperture ( 20 ). The assembly ( 2 ) also includes, (b) a rigid support ( 29 ) having substantially opposed first ( 32 ) and second ( 35 ) surfaces, and an aperture ( 38 ). The assembly ( 2 ) further includes, (c) a locking device ( 41 ) positioned at least partially around aperture ( 38 ) of rigid support ( 29 ). Locking device ( 41 ) includes at least one shelf ( 44, 47 ) extending out over a portion of the first surface ( 32 ) of rigid support ( 29 ). The shelf (e.g.,  44 ) and a portion (e.g.,  53 ) of the first surface ( 32 ) of rigid support ( 29 ) residing thereunder together define a tapered slot (e.g.,  62 ), having an open end ( 59 ) and a closed end ( 56 ). The second surface ( 17 ) of thin film data storage carrier ( 11 ) abuts at least a portion of the first surface ( 32 ) of rigid support ( 29 ). The aperture ( 20 ) of data storage carrier ( 11 ), and the aperture ( 38 ) of rigid support ( 29 ) are substantially aligned. Thin film data storage carrier ( 11 ) is reversibly fixed to rigid support ( 29 ) by means of the tab (e.g.,  23  and  26 ) of data storage carrier ( 11 ) being reversibly received within the tapered slot (e.g.,  62  and  62 ′). Also described is a thin film data storage carrier support ( 5 ), and a thin film data storage carrier having a cruciform aperture ( 91, 114 ) therein.

DESCRIPTION OF THE INVENTION

[0001] The present invention relates to a digital data storage assemblythat includes a thin film data storage carrier having an aperture, arigid support having an aperture, and a locking device positioned atleast partially around the aperture of the rigid support. The lockingdevice includes at least one shelf that extends out over the uppersurface of the rigid support, and the two together define a tapered slothaving an open end and a closed end. The thin film data storage carrierhas at least one tab that extends partially into the aperture thereof,and is preferably optically readable, e.g., a thin film compact disc.The thin film data storage carrier is reversibly fixed to the rigidsupport by means of the tab being reversibly received and fixed withinthe tapered slot (e.g., by means of rotating the thin film data storagecarrier around the locking device).

[0002] Data storage carriers include those that are optically readable,such as compact discs, rewritable compact discs, video discs and DVDdiscs. Optically readable data storage carriers, such as compact discs,are typically rigid and are fabricated by processes that include athermoplastic injection molding step. The injection molding steptypically limits the number of units that can be prepared in a givenamount of time. In addition, rigid optically readable data storagecarriers, such as rigid compact discs, have space and storageconfiguration requirements that can limit marketing and transportthereof. For example, rigid compact discs must be physically stored andtransported in such a way as to minimize bending, which can result incracking or catastrophic breakage of the discs.

[0003] More recently, thin film data storage carriers have beendeveloped, such as thin film flexible compact discs, that combine theadvantages of rigid compact discs (e.g., high data storage capacity)with improved physical storage and transport capabilities. Theproduction rates of thin film flexible data storage carriers aregenerally greater than those of rigid data storage carriers. Typically,thin film flexible data storage carriers can be prepared in the absenceof a limiting injection molding step, e.g., by means of cuttingdata-embossed thin film flexible discs out of a sheet of thermoplasticmaterial.

[0004] Thin film flexible data storage carriers typically must befurther supported, for example by means of a rigid adapter or lens, ifused in an optical digital accessing apparatus originally adapted foruse with rigid carriers, such as rigid compact discs. Rigid adaptersdeveloped thus far, typically are complicated to use and/or do notadequately reversibly fix the thin film data carrier in place.Reversibly fixing the thin film data carrier to the rigid adapter allowsfor ease of switching thin film data carriers, and adequately holdingthe thin film data carrier in place during its use within an opticaldigital accessing apparatus, e.g., a compact disc player.

[0005] It is desirable to further develop thin film data storageassemblies that provide ease of use. In addition, it would be desirablethat such newly developed thin film data storage assemblies include arigid adapter to which the thin film data carrier, e.g., a thin filmflexible compact disc, can be reversibly fixed.

[0006] U.S. Pat. Nos. 5,579,296 and 5,869,163 disclose a thin film datastorage medium that includes a thin film data carrier, and a reusableadapter that temporally receives and supports the thin film datacarrier. The adapter may include a rotational locking mechanism having aslot with an end for receiving a tab of the thin film data carrier.

[0007] In accordance with the present invention, there is provided adigital data storage assembly comprising:

[0008] (a) a thin film data storage carrier, having substantiallyopposed first and second surfaces, i.e., substantially parallel firstand second surfaces, having an aperture, and having at least one tabextending partially into said aperture;

[0009] (b) a rigid support having substantially opposed first and secondsurfaces, i.e., substantially parallel first and second surfaces, andhaving an aperture; and

[0010] (c) a locking device positioned at least partially around saidaperture of said rigid support, said locking device comprising at leastone shelf extending out over a portion of the first surface of saidrigid support, said shelf having an upper surface and a lower surface, aportion of the first surface of said rigid support residing under saidshelf, the lower surface of said shelf and said portion of said firstsurface of said rigid support residing under said shelf togetherdefining a tapered slot dimensioned to reversibly receive and reversiblyfix the tab of said thin film data storage carrier, said tapered slothaving an open end and a closed end,

[0011] wherein the second surface of said thin film data storage carrierabuts at least a portion of the first surface of said rigid support, theaperture of said thin film data storage carrier (a), and the aperture ofsaid rigid support (b) are substantially aligned, and said thin filmdata storage carrier is reversibly fixed to said rigid support by meansof the tab of said thin film data storage carrier being reversiblyreceived within said tapered slot.

[0012] In further accordance with the present invention, there isprovided a thin film data storage carrier support comprising:

[0013] (i) a rigid support having substantially opposed first and secondsurfaces, and having an aperture; and

[0014] (ii) a locking device positioned at least partially around saidaperture of said rigid support, said locking device comprising at leastone shelf extending out over a portion of the first surface of saidrigid support, said shelf having an upper surface and a lower surface, aportion of the first surface of said rigid support residing under saidshelf, the lower surface of said shelf and said portion of said firstsurface of said rigid support residing under said shelf togetherdefining a tapered slot, said tapered slot having an open end and aclosed end,

[0015] wherein said tapered slot is dimensioned to reversibly receiveand reversibly fix a tab of a thin film data storage carrier asdescribed above, and thereby allow the thin film data storage carrier tobe reversibly fixed to the rigid support of the thin film data storagecarrier support.

[0016] In accordance with the present invention, there is also provideda thin film data storage carrier having a cruciform aperture therein.

[0017] The features that characterize the present invention are pointedout with particularity in the claims, which are annexed to and form apart of this disclosure. These and other features of the invention, itsoperating advantages and the specific objects obtained by its use willbe more fully understood from the following detailed description andaccompanying drawings.

[0018] Unless otherwise indicated, all numbers or expressions, such asthose expressing structural dimensions, process conditions, etc. used inthe specification and claims are understood as modified in all instancesby the term “about.”

BRIEF DESCRIPTION OF THE DRAWINGS

[0019]FIG. 1 is a representative exploded view of a digital data storageassembly according to the present invention;

[0020]FIG. 2 is a representative section of the shelf of the lockingdevice of FIG. 1, along line A-A;

[0021]FIG. 3 is a representative top-down view of a locking deviceaccording to the present invention;

[0022]FIG. 4, is a representative perspective view of a locking deviceaccording to the present invention;

[0023]FIG. 5 is a representative top-down view of a rigid supportincluding a locking device according to the present invention;

[0024]FIG. 6 is a representative perspective view of a rigid supportaccording to the present invention that has a recessed area forreceiving a thin film data storage carrier (not shown);

[0025]FIG. 7 is a representative top-down view of a thin film datastorage carrier according to the present invention, having a cruciformaperture therein;

[0026]FIG. 8 is a representative top-down view of a thin film datastorage carrier according to the present invention, having a cruciformaperture that is defined by two pairs of opposed arcuate sides;

[0027]FIG. 9 is a representative section of a locking device similar tothat of FIG. 2, but wherein the lower surface of the shelf is angleddown towards that portion of the horizontal first surface of the rigidsupport residing thereunder;

[0028]FIG. 10 is a representative section of a locking device similar tothat of FIG. 2, but wherein each of the lower surface of the shelf andthat portion of the first surface of the rigid support residingthereunder are angled down and up respectively towards each other; and

[0029]FIG. 11 is a representative section of the locking device depictedin FIG. 10, with angles of the lower surface of the shelf, the surfaceresiding thereunder and the ramped side being further illustrated.

[0030] In FIGS. 1 through 11, like reference numerals and charactersdesignate the same components and structural features.

DETAILED DESCRIPTION OF THE INVENTION

[0031] Referring now to FIG. 1 of the drawing figures, there is shown anexploded perspective view of a digital data storage assembly 2 accordingto the present invention. Assembly 2 includes a thin film data storagecarrier 11. Carrier 11 has substantially opposed first 14 and second 17surfaces and an aperture 20. Second surface 17 is not directly visiblein FIG. 1. First 14 and second 17 surfaces can also be described asbeing substantially parallel surfaces. Aperture 20 may be locatedanywhere in data carrier 11. However, aperture 20 is preferably locatedor positioned in a central region of data carrier 11, e.g., in the areaof the center of gravity of data carrier 11. More preferably, the centerof gravity of data carrier 11 is located in the center of aperture 20.

[0032] Data carrier 11 also includes at least one tab, 23 and 26, thatextends partially into aperture 20. As used herein and in the claims, by“extends partially into aperture 20” is meant that tabs 23 and 26 donot, either separately or together, extend all the across aperture 20.Tabs 23 and 26 may be continuous with the material of data carrier 11,or alternatively may be separately adhered thereto, e.g., by means ofadhesives, as is known to the skilled artisan. Preferably, tabs 23 and26 are continuous with the material of data carrier 11.

[0033] The aperture of the thin film data storage carrier may be of anysuitable configuration, examples of which include, but are not limitedto substantially circular, elliptical, triangular, square, rectangular,hexagonal, cruciform and irregular. In an embodiment of the presentinvention, the aperture of the thin film data storage carrier iscruciform. With reference to FIG. 7, thin film data storage carrier 88,has a cruciform aperture 91 therein. Aperture 91 is defined in part bytwo pairs of substantially opposed and substantially straight sides oredges (terminal sides or edges), 94 and 94′, and 97 and 97′. Datastorage carrier 88 also has two tabs 98 and 95 that each extendpartially into aperture 91.

[0034] In a further embodiment of the present invention, the thin filmdata storage carrier has a cruciform aperture that is defined in part bytwo pairs of substantially opposed and substantially arcuate sides. Withreference to FIG. 8, data storage carrier 111 has an cruciform aperture114, which is defined in part by two pairs of substantially opposedarcuate sides or edges (e.g., terminal sides or edges), 117 and 117′,and 120 and 120′. Data storage carrier 111 also includes two tabs 118and 121 that each extend partially into aperture 114.

[0035] Data storage assembly 2 also includes a rigid support 29 havingsubstantially opposed first 32 and second 35 surfaces, and an aperture38. In FIG. 1, second surface 35 is not directly visible. First 32 andsecond 35 surfaces can also be described as being substantially parallelsurfaces. Rigid support 29 also includes a locking device 41 that ispositioned at least partially around aperture 38. A representativetop-down view of rigid support 29 is shown in FIG. 5.

[0036] Locking device 41 includes at least one shelf (44, 47). Withreference to FIG. 2, shelf 44 has an upper surface 45 and a lowersurface 50. A portion 53 of first surface 32 of rigid support 29 residesunder shelf 44. Lower surface 50 of shelf 44 and that portion 53 offirst surface 32 that resides under shelf 44 together define a taperedslot 62. Tapered slot 62 has an open end 59 and a closed end 56.

[0037] Aperture 38 may be located anywhere in rigid support 29. However,aperture 38 is preferably located or positioned in a central region ofrigid support 29, e.g., in the area of the center of gravity of rigidsupport 29. More preferably, the center of gravity of rigid support 29is located in the center of aperture 38. The aperture of the rigidsupport may be of any suitable configuration, examples of which include,but are not limited to substantially circular, elliptical, triangular,square, rectangular, hexagonal, cruciform and irregular. In a preferredembodiment of the present invention, the aperture of the rigid supportis substantially circular.

[0038] When data storage assembly 2 is assembled, second surface 17 ofdata storage carrier 11 abuts at least a portion of first surface 32 ofrigid support 29. Aperture 20 of data carrier 11 and aperture 38 ofrigid support 29 are substantially aligned. Thin film data storagecarrier 11 is reversibly fixed to rigid support 29 by means of tabs 23and 26 being reversibly received within the tapered slots (62 and 62′ ofFIG. 3) of shelves 44 and 47. For example, tab 23 is reversibly receivedwithin tapered slot 62. In particular, second surface 17 of data storagecarrier 11 is placed in abutment with first surface 32 of rigid support29, such that apertures 20 and 38 are substantially aligned. Datastorage carrier 11 is then rotated, either clockwise or counterclockwise (depending on the location of openings 59 and 59′ of slots 62and 62′, see FIG. 3), around locking device 41 such that the tabs, e.g.,tab 44, enter an open end of one of the slots of shelves 44 and 47,e.g., opening 59 of tapered slot 62 under shelf 44. As the tab is movedfurther into tapered slot 62, at least a portion of the tab becomeswedged therein. Depending on the dimension of the tapered slot, e.g.,slot 62, and the thickness of data storage carrier 11, the tab may alsoabut against closed end 56 of tapered slot 62. Closed end 56 of taperedslot 62 may be flat, as is the case in FIG. 2, or may be a point, notshown (e.g., the tapered slot forming a triangle in cross section).

[0039] In an embodiment of the present invention, aperture 38 of rigidsupport 29 is substantially circular, the shelf, e.g., shelf 44, is anannular shelf, and the tapered slot, e.g., slot 62, is an annulartapered slot. With reference FIG. 3, a representative top-down view oflocking device 41 is shown, in which annular tapered slots 62 and 62′ ofannular shelves 44 and 47 are shown by means of dashed lines. Withreference to FIG. 4, a representative perspective view of locking device41 is shown alone, without rigid support 29 thereunder. In FIG. 4,annular tapered slot 62, opening 59, closed end 56 are viewable. Inaddition, in FIG. 4, locking device 41 has an aperture 39.

[0040] In an embodiment of the present invention, and with reference toFIG. 2, tapered slot 62 is defined by lower surface 50 of shelf 44 beingsubstantially planar, and portion 53 (of first surface 32 of rigidsupport 29 residing under shelf 44) being angled (or ramped) up towardslower surface 50 of shelf 44.

[0041] In a further embodiment of the present invention, and withreference to FIG. 9, tapered slot 124 is defined by the lower surface130 of shelf 44 being angled (or ramped) down towards portion 127 offirst surface 32 of rigid support 29 residing under shelf 44. Portion127 residing under shelf 44 is substantially planar.

[0042] In another embodiment of the present invention, and withreference to FIG. 10, tapered slot 133 is defined by lower surface 136of shelf 44 being angled down towards portion 139 of first surface 32 ofrigid support 29 residing under shelf 44, and portion 139 of firstsurface 32 of rigid support 29 residing under shelf 44 is angled uptowards lower surface 136 of shelf 44.

[0043] With regard to the lower surface of the shelf of the lockingdevice, the term “angled down” means the angle of departure of the lowersurface from the horizontal. With reference to FIG. 11, lower surface136 has an angle 142 of departure from the horizontal 151. If the lowersurface of the shelf is angled down towards the portion of the firstsurface of the rigid support residing thereunder, the angle of departurefrom the horizontal is typically greater than 0° and less than 90°,e.g., from 0.5° to 20° and preferably from 1° and 10°.

[0044] With regard to the portion of the first surface of the rigidsupport residing under the shelf of the locking device, the term“angled-up” means the angle of departure of the surface portion from thehorizontal. With reference to FIG. 11, surface portion 139 has an angle145 of departure from the horizontal 148. If the portion of the firstsurface of the rigid support residing under the shelf of the lockingdevice is angled up toward the lower surface of the shelf, the angle ofdeparture from the horizontal is typically greater than 0° and less than90°, e.g., from 0.5° to 20° and preferably from 1° and 10°.

[0045] With reference to FIG. 2, open end 59 of tapered slot 62typically has a height of from 0.15 mm to 0.3 mm, preferably from 0.2 mmto 0.25 mm, and more preferably from 0.18 mm to 0.23 mm. Closed end 56may have a height of from zero to 0.3 mm, preferably from 0.25 mm to 0.3mm, and more preferably from 0.2 mm to 0.25 mm. In FIGS. 2, 9,10 and 11,closed end 56 is depicted as being flat. Closed end 56 may have anysuitable configuration, for example, it may be arcuate.

[0046] Tapered slots, 62, 124 and 133 of FIGS. 2, 9, 10 and 11 may beformed by mechanical means, e.g., by means of machining of one or bothsurfaces (e.g., surfaces 50 and/or 53). When the locking device and/orthe rigid support are fabricated from thermoplastic material, thesurfaces that define the tapered slot are preferably configured (orangled) during the molding process.

[0047] Locking device 41 may be fabricated from materials including, butnot limited to, glass, plastic and metal. Locking device 41 may have aunitary (or substantially continuous) structure, or it may fabricatedfrom a plurality of (e.g., at least 2) separate components. Preferably,locking device 41 has a unitary (or substantially continuous) structure.Typically, locking device 41 is fabricated from thermoplastic orthermoset plastic materials. Preferably, locking device 41 is fabricatedfrom a thermoplastic material selected from thermoplastic polyurethane,thermoplastic polyurea, thermoplastic polyimide, thermoplasticpolyamide, thermoplastic polyamideimide, thermoplastic polyester,thermoplastic polycarbonate, thermoplastic polysulfone, thermoplasticpolyketone, thermoplastic polypropylene, thermoplasticacrylonitrile-butadiene-styrene and thermoplastic compositionscontaining one or more thereof.

[0048] In an embodiment of the present invention, the thermoplasticmaterial of locking device 41 is reinforced with a material selectedfrom glass fibers, carbon fibers, metal fibers, polyamide fibers andmixtures thereof. Reinforcing materials, such as glass fibers, aretypically treated with a sizing to enhance their incorporation andcompatibility with the thermoplastic material. If used, thereinforcement material, e.g., glass fibers, is typically present in thethermoplastic materials of locking device 41 in a reinforcing amount,e.g., in an amount of from 5 percent by weight to 60 percent by weight,based on the total weight of locking device 41.

[0049] With reference to FIG. 2, shelf 44 of locking device 41 has aclosed side that may optionally include a ramp 65 that is substantiallyopposite from open end 59 of tapered slot 62. Ramp 65 is angled downfrom upper surface 45 of shelf 44 to first surface 32 of rigid support29. Ramp 65 facilitates the removal of thin film data storage carrier 11from locking device 41 and rigid support 29. For purposes ofillustration, as data storage carrier 11 is rotated, e.g., clockwise,and tabs 23 and 26 are turned out of slots 62 and 62′, a portion of datastorage carrier 11 defining aperture 20 slides up ramp 65 onto uppersurface 45 of shelf 44, which serves to concurrently lift or raise atleast a portion of second surface 17 of data storage carrier 11 up offof first surface 32 of rigid support 29.

[0050] With reference to ramp 65, the term “angled down” refers to theangle of departure of the ramp from the horizontal, e.g., relative tothe upper surface of the shelf. With reference to FIG. 11, ramp 65 hasan angle 154 of departure from the horizontal 157. The angle ofdeparture 154 from the horizontal 157 of ramp 65 is typically greaterthan 0° and less than 90°, e.g., from 20° to 60° and preferably from 30°to 45°.

[0051] Rigid support 29 is preferably fabricated from a material that istransparent to a laser beam, e.g., the laser beam of a digital accessingapparatus. Digital accessing appartae include, but are not limited tocompact disc players, rewritable compact disc players, video discplayers and DVD players. Such laser beam transparent materials include,for example, thermoplastic polymer, inorganic glass, and combinationsthereof. Preferably, rigid support 29 is fabricated from a thermoplasticpolymer selected from: polycarbonate; polyethylene-terephthalate;polystyrene; polyurethane elastomers; graft copolymers prepared frommonomers comprising styrene and a diene rubber; cyclic polyolefins;acrylic polymers; and combinations thereof.

[0052] Rigid support 29 may optionally be both fabricated from athermoplastic material and dimensioned to act as a lens that serves tofocus a laser beam, e.g., the laser beam of a digital accessingapparatus, onto second surface 17 of data storage carrier 11, inaccordance with art-recognized methods. Rigid support 29 typically has athickness of from 1.04 mm to 1.09 mm, e.g., a thickness of 1.06 mm.Rigid support 29 may have any suitable configuration, e.g., circular,elliptical, square, rectangular or polygonal (e.g., pentagonal andhigher). Preferably, rigid support 29 has a substantially circularconfiguration, e.g., having a diameter of 12 cm.

[0053] With reference to FIG. 6, rigid support 68 has a recessed area83. Recessed area 83 is defined in part by at least a portion of firstsurface 82 of rigid support 68. Recessed area 83 is further defined byside wall 85. Recessed area 83 is sized (or dimensioned) to reversiblyreceive thin film data storage carrier 11. Aperture 38 of rigid support68, and locking device 41 associated therewith, are both located withinrecessed area 83. Such a recessed configuration serves to minimize theoccurrence of air being driven between second surface 17 of data storagecarrier 11 and first surface 82 of rigid support 68 during spinning ofthe assembly by the spindle drive of a disc drive system. Air beingdriven between these surfaces can result in lifting (or flapping) ofdata storage carrier 11 up off of the rigid support, resulting in, forexample, interruption of optical digital reading of the data storagecarrier.

[0054] When both fabricated from thermoplastic material, rigid support29 and locking device 41 may be formed together as a single continuousarticle by means of art-recognized injection molding processes, e.g.,single injection or multi-injection molding processes. Typically, rigidsupport 29 and locking device 41 are formed separately, e.g., each beingformed by means of injection molding, and then fixed to one another in asubsequent step. Fixing of locking device 41 to rigid support 29 may beachieved by art-recognized methods which include, but are not limitedto, the use of adhesives and high frequency thermoplastic weldingtechniques.

[0055] Thin film data storage carrier 11 is preferably a thin filmflexible data storage carrier. As used herein and in the claims, theterms “flexible” (with regard to the thin film data storage carrier) and“rigid” (with regard to the rigid support) are relative to each other.That is, the rigid support is more rigid than the flexible thin filmdata storage carrier, and correspondingly, the flexible thin film datastorage carrier is more flexible than the rigid support. The rigidsupport typically has a rigidity similar to that of a rigid compact diskfabricated from thermoplastic polycarbonate and having a thickness of1.2 mm. Generally, a sheet of thermoplastic polycarbonate having athickness of less than or equal to 0.6 mm, e.g., 0.2 mm, is consideredto be flexible, and a sheet of thermoplastic polycarbonate having athickness of greater than 0.6 mm, e.g., 1.2 mm, is considered to berigid.

[0056] The thin film data storage carrier 11 may be selected from, forexample, thin film compact discs, thin film rewritable compact discs,thin film video discs and thin film DVD discs. Thin film data storagecarrier 11 includes at least one layer of a thermoplastic materialselected independently from polycarbonate, polyethylene-terephthalate;polystyrene; graft copolymers prepared from monomers comprising styreneand a diene rubber; cyclic polyolefins; acrylic polymers; andcombinations thereof. Preferably, thin film data storage carrier 11 hasa single thermoplastic layer of thermoplastic polycarbonate.

[0057] Thin film data storage carrier 11 may be fabricated by means ofart-recognized methods. In the case of a thin film compact disc,typically a single layer thermoplastic sheet, e.g., a sheet ofthermoplastic polycarbonate, is drawn continuously off of a rollthereof, and is then brought into contact with a cylindricalmicroembossing roll. The microembossing roll is generally fabricatedfrom metal, and has microembossing features etched into its surface.Digital data is microembossed onto the thermoplastic sheet upon contactwith the microembossing roll. The thermoplastic sheet may be metalized(e.g., with aluminum and by means of art-recognized vacuum sputteringtechniques) either before or after the microembossing step (preferablyafter). A protective coating, e.g., a hard-coat, is then typicallyapplied to the microembossed surface of the thermoplastic sheet.Printing of the plastic sheet may optionally be performed next, followedby additional optional coating steps. In the next step, the thin filmdata storage carrier 11 is removed from the plastic sheet by means of adie cut removal operation, and then optionally packaged fordistribution. Die cut formation of aperture 20 and tabs 23 and 26 may beperformed prior to, concurrent with or subsequent to the die cut removaloperation.

[0058] Thin film data storage carrier 11 may have a configurationselected from, for example, circular, elliptical, rectangular, squareand polygonal (e.g., pentagonal and higher). Preferably, thin film datastorage carrier 11 is substantially circular, e.g., having a diameter of12 cm. The thickness of thin film data storage carrier 11 can varywidely. Typically, thin film data storage carrier 11 has a thickness offrom 0.1 mm to 0.3 mm, preferably from 0.15 mm to 0.25 mm, and morepreferably from 0.18 mm to 0.2 mm.

[0059] In an embodiment of the present invention, when the digital dataassembly is assembled, the substantially aligned apertures (20 and 38)of thin film data storage carrier 11 and rigid support 29 are each sizedto reversibly receive a spindle drive of a disc drive system (not shown)selected from, for example, compact disc players, rewritable compactdisc players, video disc players and DVD disc players.

[0060] In a particularly preferred embodiment of the present invention,and with further reference to FIGS. 1 and 3, aperture 38 of rigidsupport 29 is substantially circular, and aperture 20 of thin film datastorage carrier 11 is sized to fit around both of aperture 38 andlocking device 41. Thin film data storage carrier 11 has two tabs 23 and26 extending partially into aperture 20 of data storage carrier 11. Tabs23 and 26 are positioned substantially 180° one from the other.Alternatively, data carrier 88 of FIG. 7 having tabs 98 and 95positioned substantially 180° from each other could be used. Furtheralternatively, data carrier 111 of FIG. 8 having tabs 118 and 121positioned substantially 180° from each other could be used. Lockingdevice 41 has two tapered annular slots (62 and 62′) positionedsubstantially 180° one from the other. The open ends 59 and 59′ oftapered annular slots 62 and 62′ are offset one from the other such thattabs 23 and 26 are each reversibly received and reversibly fixed intoannular tapered slots 62 and 62′ by means of rotating (e.g., manually)thin film data storage carrier 11 around locking device 41.

[0061] With reference to FIG. 3, tapered annular slots 62 and 62′ arepositioned relative to each other, such that tabs 23 and 26 arereversibly and fixedly received within the slots by means of a counterclockwise rotation of data storage carrier 11 around locking device 41.Such a configuration of slots 62 and 62′ is particularly desirable whendata storage assembly 2 is itself spun clockwise within a digitalaccessing apparatus, and serves to keep tabs 23 and 26 fixed withinslots 62 and 62′.

[0062] With reference to FIGS. 1 and 2, the present invention alsoprovides a thin film data storage carrier support 5. Support 5 includesa rigid support 29 having substantially opposed first 32 and second 35surfaces (i.e., substantially parallel first 32 and second 35 surfaces),and having an aperture 38. Support 5 also includes a locking device 41positioned at least partially around aperture 38 of rigid support 29.Locking device 41 includes at least one shelf (44 and 47) extending outover a portion of the first surface 32 of rigid support 29. Shelf 44,for example, has an upper surface 45 and a lower surface 50. A portion53 of first surface 32 of rigid support 29 resides under shelf 44. Lowersurface 50 of shelf 44 and portion 53 of first surface 32 of rigidsupport 29 residing under shelf 44 together define a tapered slot 62.Tapered slot 62 has an open end 59 and a closed end 56. As describedpreviously herein, tapered slot 62 is dimensioned to reversibly receiveand reversibly fix a tab (e.g., 23 or 26) of thin film data storagecarrier 11.

[0063] Rigid support 29 and locking device 41 of thin film data storagecarrier support 5 are each as described previously herein. Thin filmdata storage carrier 11 is as described previously herein.

[0064] With reference to FIG. 7, the present invention also provides athin film data storage carrier 88 having a cruciform aperture 91therein. Cruciform aperture 91 may be defined in part by two pairs ofsubstantially opposed and substantially straight lines (or substantiallyopposed terminal straight sides), 94 and 94′, and 97 and 97′. Datastorage carrier 88 also includes at least one tab (98 and 95) extendingpartially into cruciform aperture 91.

[0065] With reference to FIG. 8, the present invention also provides athin film data storage carrier 111 having cruciform aperture 114 that isdefined in part by two pairs of substantially opposed arcuate sides (orsubstantially opposed terminal arcuate sides), 117 and 117′, and 120 and120′. Cruciform aperture 114 includes at least one tab (118 and 121)extending partially into cruciform aperture 114. In FIGS. 7 and 8, tabs95 and 98, and tabs 118 and 121 each have a shape that is substantiallytriangular (though other configurations may be used, e.g., arcuate,square and rectangular). Thin film data storage carriers havingcruciform apertures (such as cruciform apertures 91 and 114 of FIGS. 7and 8) have been found to provide great ease by which the tabs thereof(e.g., tabs 98 and 95; or tabs 118 and 121) are reversibly received andfixed within tapered slots 62 and 62′.

[0066] The present invention has been described with reference tospecific details of particular embodiments thereof. It is not intendedthat such details be regarded as limitations upon the scope of theinvention except insofar as and to the extent that they are included inthe accompanying claims.

1-27. (Cancelled)
 28. A thin film data storage carrier having acruciform aperture therein, said cruciform aperture being defined inpart by two pairs of opposed arcuate sides, said thin film data storagecarrier having at least one tab extending partially into said cruciformaperture, said tab having a triangular shape.
 29. (Cancelled)
 30. Thethin film data storage carrier of claim 28 wherein said cruciformaperture is located in a central region of said thin film data storagecarrier.
 31. The thin film data storage carrier of claim 30, whereinsaid thin film data storage carrier has two tabs extending partiallyinto said cruciform aperture, the tabs being positioned substantially180° one from the other.